Techniques facilitating three-dimensional monolithic vertical field effect transistor logic gates are provided. A logic device can comprise a first vertical transport field effect transistor formed over and adjacent a substrate and a first bonding film deposited over the first vertical transport field effect transistor. The logic device can also comprise a second vertical transport field effect transistor comprising a second bonding film and stacked on the first vertical transport field effect transistor. The second bonding film can affix the second vertical transport field effect transistor to the first vertical transport field effect transistor. In addition, the logic device can comprise one or more monolithic inter-layer vias that extend from first respective portions of the second vertical transport field effect transistor to second respective portions of the first vertical transport field effect transistor and through the first bonding film and the second bonding film.

Representative techniques provide process steps for forming a microelectronic assembly, including preparing microelectronic components such as dies, wafers, substrates, and the like, for bonding. One or more surfaces of the microelectronic components are formed and prepared as bonding surfaces. The microelectronic components are stacked and bonded without adhesive at the prepared bonding surfaces.

Representative techniques provide process steps for forming a microelectronic assembly, including preparing microelectronic components such as dies, wafers, substrates, and the like, for bonding. One or more surfaces of the microelectronic components are formed and prepared as bonding surfaces. The microelectronic components are stacked and bonded without adhesive at the prepared bonding surfaces.

A memory die includes an alternating stack of insulating layers and electrically conductive layers located over a substrate, memory stack structures extending through the alternating stack, source regions located on, or in, the substrate, and at least one memory-side bonding pad electrically connected to the source regions. A logic die includes a power supply circuit configured to generate a supply voltage for the source regions, and at least one logic-side bonding pad electrically connected to the power supply circuit through a network of logic-side metal interconnect structures. The memory die is bonded to the logic die. The network of logic-side metal interconnect structures distributes source power from the power supply circuit over an entire area of the memory stack structures and transmits the source power to the memory die through bonded pairs of memory-side bonding pads and logic-side bonding pads.

A memory die includes an alternating stack of insulating layers and electrically conductive layers located over a substrate, memory stack structures extending through the alternating stack, source regions located on, or in, the substrate, and at least one memory-side bonding pad electrically connected to the source regions. A logic die includes a power supply circuit configured to generate a supply voltage for the source regions, and at least one logic-side bonding pad electrically connected to the power supply circuit through a network of logic-side metal interconnect structures. The memory die is bonded to the logic die. The network of logic-side metal interconnect structures distributes source power from the power supply circuit over an entire area of the memory stack structures and transmits the source power to the memory die through bonded pairs of memory-side bonding pads and logic-side bonding pads.

To reduce the influence of noise in the imaging device configured with the plurality of semiconductor chips. A first semiconductor chip includes a signal input transistor in which an input signal which is a signal corresponding to incident light is input to a control terminal, a reference input transistor which forms a differential pair along with the signal input transistor and in which a reference signal is input to a control terminal, a first signal line which delivers a change in a current flowing in one of the signal input transistor and the reference input transistor as a result of comparison between the input signal and the reference signal when the current is changed in accordance with a difference between the input signal and the reference signal, and a first pad which is electrically connected to the first signal line. A second semiconductor chip includes a processing circuit which processes the result of the comparison, a second signal line which is electrically connected to the processing circuit and delivers the result of the comparison to the processing circuit, and a second pad which is electrically connected to the second signal line and the first pad.

To reduce the influence of noise in the imaging device configured with the plurality of semiconductor chips. A first semiconductor chip includes a signal input transistor in which an input signal which is a signal corresponding to incident light is input to a control terminal, a reference input transistor which forms a differential pair along with the signal input transistor and in which a reference signal is input to a control terminal, a first signal line which delivers a change in a current flowing in one of the signal input transistor and the reference input transistor as a result of comparison between the input signal and the reference signal when the current is changed in accordance with a difference between the input signal and the reference signal, and a first pad which is electrically connected to the first signal line. A second semiconductor chip includes a processing circuit which processes the result of the comparison, a second signal line which is electrically connected to the processing circuit and delivers the result of the comparison to the processing circuit, and a second pad which is electrically connected to the second signal line and the first pad.

A semiconductor chip set with double-sided off-chip bonding structure in the disclosure comprises at least one first off-chip bonding structure formed above a first surface of the semiconductor chip set, and at least one second off-chip bonding structure formed above a second surface of the semiconductor chip set, wherein the first surface is opposite to the second surface and each of the first off-chip bonding structure and the second off-chip bonding structure is used for connecting to an electrical connecting point external to the semiconductor chip set through bonding wire, through-silicon via (TSV) or micro bump.

A semiconductor chip set with double-sided off-chip bonding structure in the disclosure comprises at least one first off-chip bonding structure formed above a first surface of the semiconductor chip set, and at least one second off-chip bonding structure formed above a second surface of the semiconductor chip set, wherein the first surface is opposite to the second surface and each of the first off-chip bonding structure and the second off-chip bonding structure is used for connecting to an electrical connecting point external to the semiconductor chip set through bonding wire, through-silicon via (TSV) or micro bump.

A method of removing a substrate, comprising: forming a growth restrict mask with a plurality of striped opening areas directly or indirectly upon a GaN-based substrate; and growing a plurality of semiconductor layers upon the GaN-based substrate using the growth restrict mask, such that the growth extends in a direction parallel to the striped opening areas of the growth restrict mask, and growth is stopped before the semiconductor layers coalesce, thereby resulting in island-like semiconductor layers. A device is processed for each of the island-like semiconductor layers. Etching is performed until at least a part of the growth restrict mask is exposed. The devices are then bonded to a support substrate. The GaN-based substrate is removed from the devices by a wet etching technique that at least partially dissolves the growth restrict mask. The GaN substrate that is removed then can be recycled.